NVSS J160914+653229 , the SIMBAD biblio

NVSS J160914+653229 , the SIMBAD biblio (193 results) C.D.S. - SIMBAD4 rel 1.7 - 2021.01.26CET11:05:30

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Title First 3 Authors
2020A&A...639A..57A 93           X         2 8 ~ Cosmic dissonance: are new physics or systematics behind a short sound horizon? ARENDSE N., WOJTAK R.J., AGNELLO A., et al.
2020A&A...639A.101M 485       D     X C       10 7 ~ TDCOSMO. I. An exploration of systematic uncertainties in the inference of H0 from time-delay cosmography. MILLON M., GALAN A., COURBIN F., et al.
2020A&A...640A.105M viz 65       D     X         2 44 ~ COSMOGRAIL. XIX. Time delays in 18 strongly lensed quasars from 15 years of optical monitoring. MILLON M., COURBIN F., BONVIN V., et al.
2020A&A...642A.194G 485       D     X C       10 9 ~ TDCOSMO. III. Dark matter substructure meets dark energy. The effects of (sub)halos on strong-lensing measurements of H0. GILMAN D., BIRRER S. and TREU T.
2020ApJ...895L..29L 205       D     X         5 7 ~ Determining model-independent H0 and consistency tests. LIAO K., SHAFIELOO A., KEELEY R.E., et al.
2020ApJ...897..127W 159       D     X         4 14 ~ Cosmology-independent estimate of the Hubble constant and spatial curvature using time-delay lenses and quasars. WEI J.-J. and MELIA F.
2020ApJ...900..160L 65       D     X         2 6 ~ H0 reconstruction with Type Ia supernovae, baryon acoustic oscillation and gravitational lensing time delay. LYU M.-Z., HARIDASU B.S., VIEL M., et al.
2020MNRAS.492.3047H 112       D     X         3 45 ~ SHARP - VII. New constraints on the dark matter free-streaming properties and substructure abundance from gravitationally lensed quasars. HSUEH J.-W., ENZI W., VEGETTI S., et al.
2020MNRAS.493.1725K 19       D               1 6 ~ Overconstrained gravitational lens models and the Hubble constant. KOCHANEK C.S.
2020MNRAS.494.2312S 3452     A D S   X C F     72 21 ~ Constraining VLBI-optical offsets in high redshift galaxies using strong gravitational lensing. SPINGOLA C. and BARNACKA A.
2020MNRAS.494.6072S 47           X         1 18 ~ STRIDES: a 3.9 per cent measurement of the Hubble constant from the strong lens system DES J0408-5354. SHAJIB A.J., BIRRER S., TREU T., et al.
2020MNRAS.497L..56Y 187           X   F     3 5 ~ The first simultaneous measurement of Hubble constant and post-Newtonian parameter from time-delay strong lensing. YANG T., BIRRER S. and HU B.
2019A&A...628L...7T 90           X         2 4 ~ The Hubble constant determined through an inverse distance ladder including quasar time delays and Type Ia supernovae. TAUBENBERGER S., SUYU S.H., KOMATSU E., et al.
2019A&A...629A..97B viz 45           X         1 11 ~ COSMOGRAIL. XVIII. time delays of the quadruply lensed quasar WFI2033-4723. BONVIN V., MILLON M., CHAN J.H.-H., et al.
2019ApJ...886L..23L 197       D     X C       4 4 ~ A model-independent determination of the Hubble constant from lensed quasars and supernovae using Gaussian process regression. LIAO K., SHAFIELOO A., KEELEY R.E., et al.
2019ApJ...887..126G 45           X         1 13 ~ Gravitational lens system PS J0147+4630 (Andromeda's Parachute): main lensing galaxy and optical variability of the quasar images. GOICOECHEA L.J. and SHALYAPIN V.N.
2019MNRAS.484.4726B 179           X   F     3 8 ~ H0LiCOW - IX. Cosmographic analysis of the doubly imaged quasar SDSS 1206+4332 and a new measurement of the Hubble constant. BIRRER S., TREU T., RUSU C.E., et al.
2019MNRAS.489.2097B 90           X         2 8 ~ Astrometric requirements for strong lensing time-delay cosmography. BIRRER S. and TREU T.
2019Sci...365.1134J 13 ~ A measurement of the Hubble constant from angular diameter distances to two gravitational lenses. JEE I., SUYU S.H., KOMATSU E., et al.
2018MNRAS.475.2438H 758       D     X C F     16 8 8 Flux-ratio anomalies from discs and other baryonic structures in the Illustris simulation. HSUEH J.-W., DESPALI G., VEGETTI S., et al.
2018MNRAS.476.5075S 17       D               2 103 6 Gravitational lensing reveals extreme dust-obscured star formation in quasar host galaxies. STACEY H.R., McKEAN J.P., ROBERTSON N.C., et al.
2017MNRAS.465.4634D 44           X         1 9 15 H0LiCOW. VI. Testing the fidelity of lensed quasar host galaxy reconstruction. DING X., LIAO K., TREU T., et al.
2017MNRAS.465.4895W 89           X         2 13 53 H0LiCOW - IV. Lens mass model of HE 0435-1223 and blind measurement of its time-delay distance for cosmology. WONG K.C., SUYU S.H., AUGER M.W., et al.
2017MNRAS.465.4914B viz 485     A D     X C       11 9 156 H0LiCOW - V. New COSMOGRAIL time delays of HE 0435-1223: H0 to 3.8 per cent precision from strong lensing in a flat ΛCDM model. BONVIN V., COURBIN F., SUYU S.H., et al.
2017MNRAS.467.3970G 213           X   F     4 34 18 Strong lensing signatures of luminous structure and substructure in early-type galaxies. GILMAN D., AGNELLO A., TREU T., et al.
2017MNRAS.468.2590S 905   K A D     X C F     20 6 67 H0LiCOW - I. H0 Lenses in COSMOGRAIL's Wellspring: program overview. SUYU S.H., BONVIN V., COURBIN F., et al.
2017MNRAS.470.4838S viz 85           X         2 449 24 H0LiCOW - II. Spectroscopic survey and galaxy-group identification of the strong gravitational lens system HE 0435-1223. SLUSE D., SONNENFELD A., RUMBAUGH N., et al.
2017MNRAS.471.3079H 44           X         1 2 3 Constraints on a possible evolution of mass density power-law index in strong gravitational lensing from cosmological data. HOLANDA R.F.L., PEREIRA S.H. and JAIN D.
2017MNRAS.472.4038A 43           X         1 12 10 Models of the strongly lensed quasar DES J0408-5354. AGNELLO A., LIN H., BUCKLEY-GEER L., et al.
2016A&ARv..24...11T 509           X C       11 7 53 Time delay cosmography. TREU T. and MARSHALL P.J.
2016ApJ...821..111K 42           X         1 5 2 On the problem of deformed spherical systems in modified newtonian dynamics. KO C.-M.
2016MNRAS.457.4147F 42           X         1 8 2 Gravitational microlensing as a probe for dark matter clumps. FEDOROVA E., SLIUSAR V.M., ZHDANOV V.I., et al.
2016MNRAS.458.3830A 17       D               2 11 7 Spectroscopy and high-resolution imaging of the gravitational lens SDSS J1206+4332. AGNELLO A., SONNENFELD A., SUYU S.H., et al.
2016MNRAS.462.1405J 43           X         1 2 2 The influence of weak lensing on measurements of the Hubble constant with quad-image gravitational lenses. JAROSZYNSKI M. and SKOWRON J.
2016MNRAS.462.3255C 50           X         1 2 16 Observational selection biases in time-delay strong lensing and their impact on cosmography. COLLETT T.E. and CUNNINGTON S.D.
2015A&A...580A..38R 222       D     X C       5 50 19 H0 from ten well-measured time delay lenses. RATHNA KUMAR S., STALIN C.S. and PRABHU T.P.
2015ApJS..219...29M viz 675       D     X C       16 10653 13 A spectroscopic survey of the fields of 28 strong gravitational lenses. MOMCHEVA I.G., WILLIAMS K.A., COOL R.J., et al.
2015MNRAS.448.2704I 389       D S   X         9 8 18 Constraints on warm dark matter from weak lensing in anomalous quadruple lenses. INOUE K.T., TAKAHASHI R., TAKAHASHI T., et al.
2015MNRAS.450.1042R 247           X         6 30 5 Radio monitoring campaigns of six strongly lensed quasars. RUMBAUGH N., FASSNACHT C.D., McKEAN J.P., et al.
2014ApJ...788L..35S 123           X         2 2 85 Cosmology from gravitational lens time delays and Planck data. SUYU S.H., TREU T., HILBERT S., et al.
2014ApJS..213....3M viz 16       D               1 28358 19 The Low-frequency Radio Catalog of flat-spectrum sources. MASSARO F., GIROLETTI M., D'ABRUSCO R., et al.
2014MNRAS.437..600S 179       D     X         5 40 30 Hubble constant and dark energy inferred from free-form determined time delay distances. SERENO M. and PARAFICZ D.
2014MNRAS.441..127G 244           X   F     5 18 4 Measuring gravitational lens time delays using low-resolution radio monitoring observations. GURKAN G., JACKSON N., KOOPMANS L.V.E., et al.
2014MNRAS.445..694T 47           X         1 2 13 Statistical and systematic uncertainties in pixel-based source reconstruction algorithms for gravitational lensing. TAGORE A.S. and KEETON C.R.
2013A&A...559A..37S 90           X         2 8 80 Mass-sheet degeneracy, power-law models and external convergence: Impact on the determination of the Hubble constant from gravitational lensing. SCHNEIDER P. and SLUSE D.
2013ApJ...766...70S 1200     A S   X C       26 2 184 Two accurate time-delay distances from strong lensing: implications for cosmology. SUYU S.H., AUGER M.W., HILBERT S., et al.
2013ApJ...768...39G 1463   K A D S   X C       35 2 37 Improving the precision of time-delay cosmography with observations of galaxies along the line of sight. GREENE Z.S., SUYU S.H., TREU T., et al.
2013MNRAS.429L..35A 267     A S   X C       5 5 13 Lensing and dynamics in two simple steps. AGNELLO A., AUGER M.W. and EVANS N.W.
2013MNRAS.431.1528B 40           X         1 22 4 Bayesian approach to gravitational lens model selection: constraining H0 with a selected sample of strong lenses. BALMES I. and CORASANITI P.S.
2013MNRAS.432..679C 143           X         3 2 47 Reconstructing the lensing mass in the universe from photometric catalogue data. COLLETT T.E., MARSHALL P.J., AUGER M.W., et al.
2013MNRAS.436.2120N 80             C       1 17 5 Do gravitational lens galaxies have an excess of luminous substructure ? NIERENBERG A.M., OLDENBURG D. and TREU T.
2012A&A...538A..99S 715     A D     X C       18 72 45 COSMOGRAIL: the COSmological MOnitoring of GRAvItational lenses. X. Modeling based on high-precision astrometry of a sample of 25 lensed quasars: consequences for ellipticity, shear, and astrometric anomalies. SLUSE D., CHANTRY V., MAGAIN P., et al.
2012ApJ...752..163S 53           X         1 4 104 Evidence for dark matter contraction and a salpeter initial mass function in a massive early-type galaxy. SONNENFELD A., TREU T., GAVAZZI R., et al.
2012ApJ...755...31C viz 16       D               2 311 26 Testing the dark energy with gravitational lensing statistics. CAO S., COVONE G. and ZHU Z.-H.
2012MNRAS.420.2944W 135       D     X   F     3 41 5 The fundamental surface of quad lenses. WOLDESENBET A.G. and WILLIAMS L.L.R.
2011A&A...536A..44E 393     A D     X C F     9 22 22 Time delays for eleven gravitationally lensed quasars revisited. EULAERS E. and MAGAIN P.
2011ApJ...740...97L 566       D     X C       14 27 23 Resolving the baryon-fraction profile in lensing galaxies. LEIER D., FERRERAS I., SAHA P., et al.
2011ApJ...741..117C 39           X         1 18 23 The effects of halo-to-halo variation on substructure lensing. CHEN J., KOUSHIAPPAS S.M. and ZENTNER A.R.
2011ApJS..192...18K 477           X C       6 17 6896 Seven-year Wilkinson Microwave Anisotropy Probe (WMAP) observations: cosmological interpretation. KOMATSU E., SMITH K.M., DUNKLEY J., et al.
2011MNRAS.410.2167F 645       D     X C F     15 21 35 Galaxy number counts and implications for strong lensing. FASSNACHT C.D., KOOPMANS L.V.E. and WONG K.C.
2010A&A...511A..53V viz 16       D               1 107466 32 The SPECFIND V2.0 catalogue of radio cross-identifications and spectra. SPECFIND meets the Virtual Observatory. VOLLMER B., GASSMANN B., DERRIERE S., et al.
2010AJ....139.1935S 39           X         1 8 0 The optimal gravitational lens telescope. SURDEJ J., DELACROIX C., COLEMAN P., et al.
2010ARA&A..48...87T 315           X C       7 25 170 Strong lensing by galaxies. TREU T.
2010ARA&A..48..673F 80           X         2 45 240 The Hubble constant. FREEDMAN W.L. and MADORE B.F.
2010ApJ...709..552C 897     A D     X   F     23 105 10 Identifying anomalies in gravitational lens time delays. CONGDON A.B., KEETON C.R. and NORDGREN C.E.
2010ApJ...711..201S 3945 T K A D S   X C F     98 17 224 Dissecting the gravitational lens

. II. Precision measurements of the Hubble constant, spatial curvature, and the dark energy equation of state.
2010ApJ...711..246F 157           X C F     2 15 45 Improved constraints on the gravitational lens Q0957+561. II. Strong lensing. FADELY R., KEETON C.R., NAKAJIMA R., et al.
2010ApJ...712.1378P 212       D     X   F     5 20 42 The Hubble constant inferred from 18 time-delay lenses. PARAFICZ D. and HJORTH J.
2010ApJ...715..793G 133       D     X         4 21 8 Fold lens flux anomalies: a geometric approach. GOLDBERG D.M., CHESSEY M.K., HARRIS W.B., et al.
2010ApJ...716.1579L 133       D     X         4 48 34 Cosmic evolution of virial and stellar mass in massive early-type galaxies. LAGATTUTA D.J., FASSNACHT C.D., AUGER M.W., et al.
2010ApJ...716L.185L 39           X         1 12 20 Adaptive optics observations of B0128+437: a low-mass, high-redshift gravitational lens. LAGATTUTA D.J., AUGER M.W. and FASSNACHT C.D.
2010ApJ...724..511A 80           X         2 59 248 The Sloan lens ACS survey. X. Stellar, dynamical, and total mass correlations of massive early-type galaxies. AUGER M.W., TREU T., BOLTON A.S., et al.
2010MNRAS.402.2031C 16       D               2 33 31 Galaxy evolution from strong-lensing statistics: the differential evolution of the velocity dispersion function in concord with the Λ cold dark matter paradigm. CHAE K.-H.
2010MNRAS.403..826J 328       D     X C F     7 26 14 Satellites in the field and lens galaxies: SDSS/COSMOS versus SLACS/CLASS. JACKSON N., BRYAN S.E., MAO S., et al.
2010MNRAS.405.2579O 84           X         1 2 180 Gravitationally lensed quasars and supernovae in future wide-field optical imaging surveys. OGURI M. and MARSHALL P.J.
2009A&A...498...49C 116           X C       2 12 10 Parity dependence in strong lens systems as a probe of dark matter substructure. CHEN J.
2009A&A...504..769C 39           X         1 25 19 The global mass-to-light ratio of SLACS lenses. CARDONE V.F., TORTORA C., MOLINARO R., et al.
2009ApJ...691..277S 2154 T   A S   X C       53 7 43 Dissecting the gravitational lens
B1608+656. I. Lens potential reconstruction.
2009ApJ...706...45C 95           X         2 1 36 Cosmological constraints from gravitational lens time delays. COE D. and MOUSTAKAS L.A.
2009MNRAS.398.1235X 117           X C       2 16 63 Effects of dark matter substructures on gravitational lensing: results from the Aquarius simulations. XU D.D., MAO S., WANG J., et al.
2009MNRAS.400..875L 402       D     X C F     9 23 4 A lensing view on the fundamental plane. LEIER D.
2009RMxAC..35..195F 39           X         1 39 0 Cosmology with gravitational lenses. FALCO E.E.
2008A&A...487..831Z 78           X         2 11 24 Testing the DGP model with gravitational lensing statistics. ZHU ZONG-HONG and SERENO M.
2008ApJ...681.1017F viz 1551       D S   X C       39 34 21 The X-ray properties of moderate-redshift galaxy groups selected by association with gravitational lenses. FASSNACHT C.D., KOCEVSKI D.D., AUGER M.W., et al.
2008ApJ...685..725W 33 9 Lensed image angles: new statistical evidence for substructure. WILLIAMS L.L.R., FOLEY P., FARNSWORTH D., et al.
2008MNRAS.385.2107S 116           X         3 6 18 The effect of satellite galaxies on gravitational lensing flux ratios. SHIN E.M. and EVANS N.W.
2008MNRAS.391..959B 115           X         3 5 8 Luminous satellite galaxies in gravitational lenses. BRYAN S.E., MAO S. and KAY S.T.
2007ApJ...660....1O 1 46 101 Gravitational lens time delays: a statistical assessment of lens model dependences and implications for the global Hubble constant. OGURI M.
2007MNRAS.382..308K 39           X         1 3 6 Probing galactic dark matter in dense environments: on the strong lensing efficiency of galaxies in rich clusters. KING L.J.
2006AJ....132..999O viz 1 21 75 The Sloan Digital Sky Survey Quasar Lens Search. I. Candidate selection algorithm. OGURI M., INADA N., PINDOR B., et al.
2006ApJ...641..169M viz 385 67 A spectroscopic study of the environments of gravitational lens galaxies. MOMCHEVA I., WILLIAMS K., KEETON C., et al.
2006ApJ...642...30F 39   K     O           12 41 Mass along the line of sight to the gravitational lens B1608+656: galaxy groups and implications for H0. FASSNACHT C.D., GAL R.R., LUBIN L.M., et al.
2006ApJ...646...85W 27 39 First results from a photometric survey of strong gravitational lens environments. WILLIAMS K.A., MOMCHEVA I., KEETON C.R., et al.
2006ApJ...650L..17S 1 24 51 The Hubble time inferred from 10 time delay lenses. SAHA P., COLES J., MACCIO A.V., et al.
2006ApJ...651..667F 40   K                 4 16 Three gravitational lenses for the price of one: enhanced strong lensing through galaxy clustering. FASSNACHT C.D., McKEAN J.P., KOOPMANS L.V.E., et al.
2006MNRAS.366...39S 38   K                 8 15 The anatomy of a quadruply imaged gravitational lens system. SUYU S.H. and BLANDFORD R.D.
2006MNRAS.367.1543P 10 6 Rotation in gravitational lenses. PEN U.-L. and MAO S.
2006MNRAS.373.1369C 27 15 Constraints on the velocity profiles of galaxies from strong lensing statistics and semi-analytical modelling of galaxy formation. CHAE K.-H., MAO S. and KANG X.
2005ApJ...622...81M 3 15 91 Improved cosmological constraints from gravitational lens statistics. MITCHELL J.L., KEETON C.R., FRIEMAN J.A., et al.
2005ApJ...622..106O 25 42 Discovery of two gravitationally lensed quasars with image separations of 3" from the sloan digital sky survey. OGURI M., INADA N., HENNAWI J.F., et al.
2005ApJ...623..666R 5 12 128 The evolution and structure of early-type field galaxies: a combined statistical analysis of gravitational lenses. RUSIN D. and KOCHANEK C.S.
2005ApJ...623L...5F 42 66 Stellar and total mass in early-type lensing galaxies. FERRERAS I., SAHA P. and WILLIAMS L.L.R.
2005ApJ...624....7M 50 9 Peculiar velocity and deaberration of the sky. MENZIES D. and MATHEWS G.J.
2005ApJ...625..633D viz 23 13 Chandra observations of the gravitational lenses B1600+434 and B1608+656. DAI X. and KOCHANEK C.S.
2005ApJ...630..764C 43 13 Constraints on the velocity dispersion function of early-type galaxies from the statistics of strong gravitational lensing. CHAE K.-H.
2005ApJ...635...35K 30 52 Identifying lenses with small-scale structure. II. Fold lenses. KEETON C.R., GAUDI B.S. and PETTERS A.O.
2005MNRAS.356..937S 7 7 Constraints on a quintessence model from gravitational lensing statistics. SERENO M.
2005MNRAS.357..124Y 1 18 50 The Hubble constant from the gravitational lens CLASS B0218+357 using the Advanced Camera for Surveys. YORK T., JACKSON N., BROWNE I.W.A., et al.
2004ApJ...604L...5M 3 13 83 Anomalous flux ratios in gravitational lenses: for or against cold dark matter? MAO S., JING Y., OSTRIKER J.P., et al.
2004ApJ...607L..71C 1 15 43 Constraints on scalar-field dark energy from the Cosmic Lens All-Sky Survey gravitational lens statistics. CHAE K.-H., CHEN G., RATRA B., et al.
2004ApJ...610...69K 3 19 142 Tests for substructure in gravitational lenses. KOCHANEK C.S. and DALAL N.
2004ApJ...611..739T 6 19 254 Massive dark matter halos and evolution of early-type galaxies to z ~ 1. TREU T. and KOOPMANS L.V.E.
2004MNRAS.354..343T 13 11 Lens modelling and estimate of H0in quadruply lensed systems. TORTORA C., PIEDIPALUMBO E. and CARDONE V.F.
2004PhT....57f..45K 11 0 Gravitational lenses. KOOPMANS L.V.E. and BLANDFORD R.D.
2003A&A...404...83N 7 9 A probability theoretical access to extragalactic microlensing. NEINDORF B.
2003ApJ...583...49K 1 11 43 Gravitational lens time delays in cold dark matter. KOCHANEK C.S.
2003ApJ...584..100S 38   K                 5 15 The gravitational lens
B1608+656. I. V-, I-, and H-band Hubble space telescope imaging.
2003ApJ...587..143R 62 118 The evolution of a mass-selected sample of early-type field galaxies. RUSIN D., KOCHANEK C.S., FALCO E.E., et al.
2003ApJ...595...29R 1 45 118 Self-similar models for the mass profiles of early-type lens galaxies. RUSIN D., KOCHANEK C.S. and KEETON C.R.
2003ApJ...595..712K 1 11 43 Extrinsic radio variability of JVAS/CLASS gravitational lenses. KOOPMANS L.V.E., BIGGS A., BLANDFORD R.D., et al.
2003ApJ...598..138K 2 23 103 Identifying lenses with small-scale structure. I. Cusp lenses. KEETON C.R., GAUDI B.S. and PETTERS A.O.
2003ApJ...599...70K 3 13 87 The Hubble constant from the gravitational lens B1608+656. KOOPMANS L.V.E., TREU T., FASSNACHT C.D., et al.
2003MNRAS.341....1M viz 4 26 216 The Cosmic Lens All-Sky Survey - I. Source selection and observations. MYERS S.T., JACKSON N.J., BROWNE I.W.A., et al.
2003MNRAS.343..639O 78 60 The redshift distribution of gravitational lenses revisited: constraints on galaxy mass evolution. OFEK E.O., RIX H.-W. and MAOZ D.
2003MNRAS.344.1029D 14 20 Strong lensing constraints on the velocity dispersion and density profile of elliptical galaxies. DAVIS A.N., HUTERER D. and KRAUSS L.M.
2002A&A...382..792C 1 4 18 A new method for the estimate of H0 from quadruply imaged gravitational lens systems. CARDONE V.F., CAPOZZIELLO S., RE V., et al.
2002A&A...383...71B 3 7 77 An optical time-delay for the lensed BAL quasar HE 2149-2745. BURUD I., COURBIN F., MAGAIN P., et al.
2002A&ARv..10..263C 59 26 Gravitational lensing in quasar samples. CLAESKENS J.-F. and SURDEJ J.
2002AAS...201.8009F 74 T                   2 0 Small groups of galaxies associated with the gravitational lenses
CLASS B1608+656 and CLASS B1600+434.
2002ApJ...571..712B 46 44 A submillimeter survey of gravitationally lensed quasars. BARVAINIS R. and IVISON R.
2002ApJ...572...25D 10 11 330 Direct detection of cold dark matter substructure. DALAL N. and KOCHANEK C.S.
2002ApJ...578...25K 4 8 116 What do gravitational lens time delays measure? KOCHANEK C.S.
2002ApJ...581..823F 112 T K                 28 87 A determination of H0with the CLASS gravitational lens
B1608+656. III. A significant improvement in the of the time delay measurements.
2002BASI...30..723N 9 1 Time delay in gravitational lens systems and cosmological parameters. NARASIMHA D.
2002MNRAS.332..951W 39   K                 5 41 Degeneracies and scaling relations in general power-law models for gravitational lenses. WUCKNITZ O.
2002MNRAS.337...26L 9 14 An investigation of gravitational lens determinations of H0in quintessence cosmologies. LEWIS G.F. and IBATA R.A.
2002PhRvL..89o1301C 2 15 101 Constraints on cosmological parameters from the analysis of the cosmic lens all sky survey radio-selected gravitational lens statistics. CHAE K.-H., BIGGS A.D., BLANDFORD R.D., et al.
2001AJ....121...21B 151 47 The distribution of redshifts in new samples of quasi-stellar objects. BURBIDGE G. and NAPIER W.M.
2001AJ....122..585S 2 3 24 Beware the nonuniqueness of EINSTEIN rings. SAHA P. and WILLIAMS L.L.R.
2001AJ....122..591R 28 14 The new two-image gravitational lens system CLASS B2319+051. RUSIN D., MARLOW D.R., NORBURY M., et al.
2001ApJ...547...50K 1 24 92 The importance of EINSTEIN rings. KOCHANEK C.S., KEETON C.R. and McLEOD B.A.
2001ApJ...549L..33R 2 13 86 Constraints on the inner mass profiles of lensing galaxies from missing odd images. RUSIN D. and MA C.-P.
2001ApJ...553..709R 1 20 71 Why is the fraction of four-image radio lens systems so high? RUSIN D. and TEGMARK M.
2001ApJ...554.1227H 10 22 Lensing properties of scale-free galaxies. HUNTER C. and EVANS N.W.
2001ApJ...557..594R 23 49 B1359+154: a six-image lens produced by a z ≃ 1 compact group of galaxies. RUSIN D., KOCHANEK C.S., NORBURY M., et al.
2001ApJ...558..119C 24 27 Chandra detects a rapid flare in the gravitationally lensed mini-broad absorption line QSO RX J0911.4+0551. CHARTAS G., DAI X., GALLAGHER S.C., et al.
2001MNRAS.320..401Z 1 6 24 Systematic uncertainties in gravitational lensing models: a semi-analytical study of PG1115+080. ZHAO H. and PRONK D.
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